Global ETD Search

121	Modélisation photochimique de la formation des électrons de conduction au sein de l'hétérojonction d'une cellule solaire organique / Photochemical Modeling of the Formation of Conduction Electrons at a Heterojunction in an Organic Solar Cell Darghouth, Ala Aldin M Hani Mahmood 22 December 2017 (has links) L'incertitude entourant la production du pétrole et la pollution associée aux fossiles combustibles ainsi que la série d'accidents bien connus de Three Mile Island, Tchernobyl et Fukushima, en plus que le désir de diversifier les sources d'énergie sont des facteurs importants qui favorisent le développement de la technologie des cellules photovoltaïques. Certaines applications de photovoltaïques organiques sont particulièrement intéressantes à cause de la possibilité d'impréssion des circuits et la création de cellules photovoltaïques flexibles sous la forme d'un ruban adhésif. À la suite des études fondamentales de Tang, que l'on appelle hétérojonction en volume (BHJ), des cellules photovoltaïques ont été créées par une séparation de phase du polymère. Certains appareils BHJ sont déjà disponibles dans le commerce, mais leur efficacité photovoltaïque est encore faible. Afin d'améliorer cette efficacité, nous proposons de modéliser le processus critique par lequel une excitation locale ( « un exciton ») se dissocie pour former une paire électron / trou conducteur. Contrairement à la majorité des physiciens specialiste dans l'état solide impliqués dans l'étude de ce problème qui semble ignorer le caractère non-Born-Oppenheimer typique de cet événement, nous prévoyons de traiter cet événement directement par la modélisation photochimique utilisant la dynamique semiclassique (saut de suface de Tully) avec laquelle nous avons déjà une certaine expérience. Comme l'objectif est la compréhension des systèmes très complexes, nous proposons des calculs exploratoires basées sur la méthode TD-DFTB, une version semiempirique de la théorie de la fonctionnelle de densité en fonction du temps (TD-DFT) pour lequel un de nous est bien connu pour son travail pionnier. L'étude sera menée en collaboration avec le groupe ORGAVOLT des développeurs de méthodes ab initio pour la modélisation des BHJs, et avec des groupes à Singapour intéressés par les BHJs, ainsi qu'avec des groupes en Allemagne spécialisés dans la DFTB. / The uncertainty surrounding petroleum production and the pollution associated with fossil fuels plus the series of well-known accidents of Three Mile Island, Chernobyl and Fukushima plus the desire to diversify energy sources are important factors favoring the development of solar cell technology. For certain applications organic photovoltaics are particularly interesting because (for example) of the possibility of printing these circuits and the creation of flexible solar cells in the form of adhesive tape. Following the seminal studies of Tang, so-called bulk heterojunction (BHJ) solarcells have been created by polymer phase separation. Some BHJ divices are already available commercially but their photovoltaic efficiency is still low. In order to aid in the improving this efficiency, we propose to model the critical process by which a local excitation (an "exciton") dissociates to form a conducting electron/hole pair. In contrast with the majority of solid-state physicists involved in studying this problem who seem to ignore the typically non-Born-Oppenheimer character of this event, we planto treat this event directly by photochemical modeling using semiclassical (Tully-type) surface-hopping dynamics with which we already have some experience. As the objective is the comprehension of highly complex systems, we propose exploratory calculations based on the TD-DFTB method, a semiemprical version of the time-dependent density-functional theory (TD-DFT) for which one of us is well-known for his pioneering work. The study will be carried out in collaboration with the ORGAVOLT group of developers of ab initio methods for modeling BHJs, and with groups in Singapore interested by BHJs, as well as with groups in Germany specializing in DFTB. Electronique organique Photochemical modeling Organic solar cell 540 530
122	Combined MD/DFT protocol for the simulation of molecular materials for organic solar cells Turelli, Michele 05 March 2021 (has links) In much of the literature about organic photovoltaics, the topic is framed within the current landscape of energy production and the research on these materials is cited as a possible solution to the energy crisis looming ahead. Despite being the most frequent, this is by no means the only perspective that can be offered. Indeed, the same research may also be set within the larger perspective offered by the field of functional materials. These materials are usually exploited for their particular responses to electrical, magnetic and chemical stimuli and are at the basis of many technologies fundamental to our society. The prominent position of functional materials in modern science is due to the emergence of novel technological needs that such materials have been able to satisfy thanks to their peculiar properties. These properties have been rationalised and mastered by expanding the theoretical description of the underlying physical mechanisms. This theoretical body, combined with the growth and diffusion of computational capabilities has fostered a change in the scientific paradigm underpinning the research effort. More and more, the predictive power of numerical approaches is exploited to lead the way in the exploration of the immense chemical space. The ultimate promise is to achieve the purpose-driven design of compounds thanks to which the molecular structure can be engineered before the actual synthesis to meet the demands dictated by a specific application. To fulfil this role, computational approaches need to be able to simulate the solid state properties at the most relevant time and length scales. If this can be accomplished then a reliable prediction of the performance can be achieved. The current work deals with the development and application of one such protocol, for the particular case of organic photovoltaic semiconductors. Given the specific application, the properties targeted are light absorption and charge transport. Particular effort is put in the simulation of local morphologies at scales above the molecular one to describe supramolecular organisation with sufficient resolution. In this thesis, the protocol is applied to two molecular systems employed in solar devices. Both systems have been selected on the basis of data suggesting that a detailed microscopic description of their behaviour could be highly informative about the aspects responsible for their photovoltaic performance. In particular, chapter 3 details the investigation of a small-molecule donor that has been shown in the literature to have a remarkable behaviour in absorption. While chapter 4 reports the study of a donor-acceptor dyad used as active layer in single-component solar devices with relatively high conversion efficiency. In both cases, the computational protocol has proven capable of providing a detailed microscopic description of the systems. The picture drawn has allowed to clarify the plausible mechanisms behind the observations and to rationalise these behaviours in a broader and more general theoretical framework. Settore CHIM/02 - Chimica Fisica
123	The Electrophoretic Deposition of Conjugated Polymer Functionalized Carbon Nanotubes for Photovoltaic Applications Casagrande, Travis V. 10 1900 (has links) <p><p lang="en-US">This experimental research thesis describes the combination of conjugated polymers and carbon nanotubes with the fields of electrophoretic deposition (EPD) and organic solar cells. Prior to these contributions, soluble conjugated polymers and carbon nanotubes that have been functionalized by them had not yet been deposited by EPD from solution or by using non-toxic solvents. Additionally, EPD had not yet been utilized to deposit the active layer in a solid organic photovoltaic device. <p lang="en-US">The EPD of soluble conjugated polymer functionalized carbon nanotubes from non-toxic solvents was achieved through an iterative process of experimentation and technique refinement. The developed EPD technique utilized the high pH region at the cathode substrate to neutralize positively charged weak polyelectrolytes macromolecules. Their functional groups were protonated using a minimized amount of acetic acid which also enabled their solubility. Deprotonation of the quaternary ammonium functional groups rendered them neutrally charged and insoluble tertiary amines. This mechanism facilitated the formation of coatings that were predictable and uniform in appearance and thickness. <p lang="en-US">Control over coating thickness was demonstrated by coatings spanning 100 nm to 10 μm. These coatings were produced by adjusting the applied voltage, solution concentration, and tuning the deposition duration. <p lang="en-US">Techniques for the fabrication of a photovoltaic device using an active layer produced by EPD were established though modifications of general organic photovoltaic device fabrication procedures. These modifications involved redesigning the photolithographic ITO etching pattern, adding an insulating barrier strip, thickening the aluminum electrode layer, and switching the top buffer layer from LiF to BCP.</p> / Master of Applied Science (MASc) electrophoretic deposition conjugated polymer carbon nanotubes organic solar cell photovoltaic electrodeposition Polymer and Organic Materials Polymer and Organic Materials
124	Charakterisierung von organischen Solarzellen an einem neu aufgebauten Laser-basierten DSR-Messplatz Fey, Thomas 23 October 2015 (has links) (PDF) Die Physikalisch-Technische Bundesanstalt (PTB) unterstützt vielfältig die Gesellschaft, Wirtschaft und Wissenschaft. Eine ihrer Kernkompetenzen als das nationale Metrologie-Institut der Bundesrepublik Deutschland ist die Messtechnik. In diesem Sinne kalibriert die Arbeitsgruppe „Solarzellen“ der PTB i. d. R. den Kurzschlussstrom unter Standardtestbedingungen (I_STC) von Referenzsolarzellen. Der I_STC von Referenzsolarzellen ist in Photovoltaik-Kalibrierketten bei der Bestimmung der Bestrahlungsstärke von zentraler Bedeutung und fließt signifikant in die Berechnung der Wirkungsgrad von Solarzellen und Solarmodulen ein. Um den I_STC einer Solarzelle mit geringster Messunsicherheit zu bestimmen, wurde die Differential Spectral Responsivity (DSR)-Methode verwendet. Sie basiert auf der Messung der differentiellen spektralen Empfindlichkeit bei unterschiedlichen Bestrahlungsstärken. Anhand dieser kann die absolute spektrale Empfindlichkeit s(λ) unter Standardtestbedingungen sowie der I_STC berechnet werden. Da jedoch die Umgebungsbedingungen meistens von den STC abweichen, reichen letztere nicht zum umfassenden Vergleich der Wirkungsgrade in der Praxis aus. Um Einflussfaktoren (Temperatur, Bestrahlungsstärke, Winkelabhängigkeit,...) genauer untersuchen zu können, wurde im Rahmen dieser Arbeit an der PTB ein neuer Laser-basierter DSR-Messplatz aufgebaut und charakterisiert. Mit dem neuen Messplatz wurden c-Si Referenzsolarzellen, organische Solarzellen auf Basis kleiner Moleküle sowie Farbstoffsolarzellen umfassend untersucht. Unter anderem wurden die elektrischen Leistungsparameter einer organischen Solarzelle (aktive Schicht: DCV5T-Me:C60) mit denen einer c-Si Solarzelle verglichen. Es zeigt sich, dass der Wirkungsgrad der organischen Solarzelle mit zunehmender Bestrahlungsstärke sinkt und mit zunehmender Temperatur steigt, während die c-Si Solarzelle ein gegensätzliches Verhalten aufweist. Darüber hinaus wurde u.a. die Winkelabhängigkeit der zweiten organischen Solarzelle (aktive Schicht: C60:DCV5T-Me(3,3)) untersucht und mit den Resultaten einer c-Si Solarzelle verglichen. Diese Untersuchungen haben ergeben, dass die Winkelabhängigkeit des Kurzschlussstroms der organischen Solarzelle im Vergleich zu einer c-Si Solarzelle insbesondere zwischen 20° < ϑ < 60° eine „Super-Kosinus-Anpassung“ aufweist. Ergänzend wurde an der PTB im Rahmen dieser Arbeit ein mobiler Messplatz für Outdoormessungen aufgebaut. Mit diesem konnten die mittels Indoor-Untersuchungen erhaltenen spektralen Empfindlichkeiten mit Outdoor-Messungen verglichen werden. Des Weiteren wurden spektrale Charakterisierungen der Himmelshalbkugel durchgeführt und Methoden für Korrekturen von Sekundärkalibrierungen untersucht. Kalibrierung primäre Kalibrierung Spektrale Empfindlichkeit Organische Solarzellen Kurzschlussstrom Standardtestbedingungen Calibration primary calibration Spectral Response organic solar cells short-circuit current standard test conditions ddc:530 rvk:VN 6057
125	Transparent Silver Nanowire Bottom Electrodes in Organic Solar Cells / Transparente Grundelektroden aus Silbernanodrähten in organischen Solarzellen Bormann, Jan Ludwig 25 January 2017 (has links) (PDF) Organic solar cells (OSCs) is an emerging photovoltaic technology that opens up new application areas where common inorganic techniques are not able to score. Some of those key features are flexibility, light weight, semitransparency, and low cost processing. The current industry-standard for the transparent electrode, indium tin oxide (ITO), cannot provide these properties because it is brittle and expensive. This thesis aims to investigate an alternative type of promising transparent electrode: silver nanowire (AgNW) networks. They exhibit similar or even better optical and electrical performance than ITO down to a sheet resistance of 12 Ohm/sq at 84% transmission (including the glass substrate). Furthermore, AgNWs are more flexible, solution-processable, and more cost-effective than ITO. However, two challenges occur during implementation as bottom electrode in OSCs. First, their inherently high roughness causes devices to shunt. Second, the AgNW network structure exhibits – in contrast to the continuous ITO – µm²-sized voids that have to be bridged electrically by the organic layers. In the first part of this thesis, solution-processed small molecule charge transport layers are investigated. In the case of hole transport layers (HTL), the host BF-DPB and the dopant NDP9 are investigated using tetrahydrofuran as a solvent. It is shown that BF-DPB is already doped by NDP9 in solution via the formation of a hybrid molecule complex. Solution-processed layers exhibit similar conductivities as compared to the reference deposition, which is thermal evaporation in high vacuum. The layers sufficiently smoothen the AgNW electrode such that DCV5T-Me:C60 organic solar cells with an efficiency up to 4.4% are obtained. Moreover, the influence of the square micrometer large network voids is investigated using HTLs of varying conductivity. As a result, a minimum conductivity of 1e−4 S/cm is needed to avoid macroscopic performance losses. Equivalent circuit simulations are performed to confirm these results. As a second planarization method, the AgNWs are buried in an insulating polymer that serves concurrently as flexible and ultrathin substrate. Out of three different polymers tested, the optical adhesive ’NOA63’ gives the best results. The roughness is strongly reduced from 30 nm down to (2 ± 1) nm. Two different OSC types are employed as testing devices with fully-flexible alumina encapsulation against moisture ingress. Maximum power conversion efficiencies of 5.0% and 5.6% are achieved with a fullerene-free cascade layer architecture and a DCV5T-Me:C60 OSC, respectively. To evaluate the applicability of these fully-flexible and encapsulated devices, degradation studies are performed under continuous illumination and a humid climate. Although employing the intrinsically stable DCV5T-Me:C60 stack design, within one day a fast degradation of the fully-flexible solar cells is observed. The degradation is attributed to AgNW electrode failure that results from photo-oxidation and -sulfurization, photo-migration, and electromigration. It is further shown that the cascade organic solar cell lacks intrinsic stability. In summary, efficient, fully-flexible, and encapsulated devices are shown. However, in terms of competitive OSCs, the low stability of AgNW electrodes is a challenge to be taken care of. In current research, this issue needs to be addressed more frequently. / Organische Solarzellen (OSZ) sind ein junges Forschungsgebiet der Photovoltaik, welches neue Anwendungsgebiete erschließt, für die herkömmliche anorganische Solarzellen nicht einsetzbar sind. Einige der Haupteigenschaften sind Flexibilität, niedriges Gewicht, Teiltransparenz und geringe Herstellungskosten. Indiumzinnoxid (ITO), der aktuelle Industriestandard transparenter Elektrodentechnologie, ist nicht in der Lage, diese Eigenschaften zu gewährleisten. Dies liegt vor allem an der Brüchigkeit von ITO und der begrenzten Verfügbarkeit von Indium, welche mit einem hohen Preis einhergeht. Das Ziel dieser Dissertation ist die Integration einer alternativen und vielversprechenden Elektrodentechnologie: Netzwerke aus Silbernanodrähten (AgNWs). Mit einem Schichtwiderstand von 12 Ohm/sq bei einer Transmission von 84% (inklusive Glassubstrat) besitzen sie ähnliche oder sogar bessere optische und elektrische Eigenschaften als ITO. Des Weiteren sind AgNW-Elektroden flexibler und kostengünstiger als ITO und aus flüssiger Phase prozessierbar. Es gibt allerdings zwei Herausforderungen, welche die Integration als Grundelektrode in OSZ erschweren. Zum einen sind AgNW-Netzwerke sehr rauh, sodass organische Bauteile kurzgeschlossen werden. Zum anderen weisen AgNW-Elektroden, im Gegensatz zu einer vollflächigen ITO-Schicht, Lücken zwischen den einzelnen Drähten auf. Diese Lücken müssen von den organischen Schichten der OSZ elektrisch überbrückt werden. Im ersten Teil der Arbeit werden daher flüssigprozessierte Ladungsträgertransportschichten aus kleinen Molekülen untersucht, welche die AgNW-Elektroden glätten und die verhältnismäßig großen Lücken füllen sollen. Im Falle von Lochleitschichten (HTL) wird BF-DPB als Matrix und NDP9 als Dotand in Tetrahydrofuran gelöst und zur Anwendung gebracht. BF-DPB wird dabei schon in Lösung von NDP9 dotiert, wobei sich ein Hybridmolekülkomplex ausbildet. Die Leitfähigkeit der entstehenden Schichten ist ähnlich zu Referenzschichten, die durch thermisches Verdampfen im Hochvakuum hergestellt wurden. Die erhaltenen HTLs glätten die AgNW-Elektroden, sodass DCV5T-Me:C60-Solarzellen mit einer Effizienz von maximal 4.4% hergestellt werden können. Weiterhin wird der Einfluss der quadratmikrometergroßen Löcher auf die makroskopische Effizienz der Solarzelle in Abhängigkeit der HTL Leitfähigkeit untersucht. Um signifikante Effizienzverluste zu verhindern, muss der HTL eine minimale Leitfähigkeit von etwa 1e−4 S/cm aufweisen. Simulationen eines Ersatzschaltkreises bestätigen hierbei die experimentellen Ergebnisse. Im zweiten Teil der Arbeit wird eine Planarisierungsmethode untersucht, in welcher die AgNWs in nichtleitfähigen Polymeren eingebettet werden. Diese Polymere fungieren anschließend als flexibles Substrat. Der optische Kleber ”NOA63” erzielt hierbei die besten Ergebnisse. Die Rauheit der AgNW-Elektroden wird von etwa 30 nm auf 1 bis 3 nm stark reduziert. Anschließend werden diese AgNW-Elektroden in zwei unterschiedlichen OSZ Konfigurationen getestet und mit einer vollflexiblen Schicht aus Aluminiumoxid gegen Wasserdampfpermeation verkapselt. Somit können maximale Effizienzen von 5% mithilfe einer organischen Kaskadenstruktur und 5.6% mit DCV5T-Me:C60 OSZ erreicht werden. Um die Anwendbarkeit dieser vollflexiblen und verkapselten OSZ zu bewerten, werden Alterungsstudien unter konstanter Beleuchtung und feuchtem Klima durchgeführt. Es wird gezeigt, dass die in das Polymer eingebettete AgNW-Elektrode aufgrund von Photooxidation und -schwefelung und Photo- und Elektromigration instabil ist. Dieser Sachverhalt ist für die Anwendung von AgNW-Elektroden in kommerziellen OSZ von großer Bedeutung und wurde in der Forschung bisher nicht ausreichend thematisiert. Elektroden Transparente Elektroden Silbernanodrähte Organische Solarzellen Degradation kleine Moleküle Lösungsmittelprozesse electrodes transparent electrodes silver nanowires organic solar cells degradation small molecules solution processes ddc:530 rvk:VN 6057
126	Intégration de nanostructures plasmoniques au sein de dispositifs photovoltaïques organiques : étude numérique et expérimentale. Vedraine, Sylvain 26 October 2012 (has links) Les cellules solaires en couches minces permettent de produire de l'énergie à bas-coût et sans émission de gaz à effet de serre. Dans le but de réaliser des dispositifs toujours plus performants, nous étudions l'impact de l'intégration de nanostructures métalliques (NSs) au sein de cellules solaires organiques (CSO). Ces NSs peuvent alors générer des effets diffusifs et des résonances issues de plasmons de surface. A l'aide d'un modèle numérique FDTD, nous démontrons que l'ingénierie plasmonique peut servir à augmenter l'absorption dans le matériau photoactif tout en limitant l'énergie perdue sous forme de chaleur dans les NSs. L'influence de paramètres opto-géométriques de structures associant matériaux organiques et effets plasmoniques est étudiée (diamètre, position des particules dans la couche et période du réseau de particules sphériques). Expérimentalement, des NSs d'argent ont été réalisées par évaporation sous vide puis intégrées dans des couches organiques. Nous avons mesuré une exaltation de l'absorption optique dans la gamme spectrale utile à la photo-conversion. Trois architectures différentes de CSO plasmonique ont été fabriquées et caractérisées par MEB, TEM et ToF-SIMS, puis modélisées, permettant d'identifier des verrous technologiques et de proposer des pistes d'amélioration. Nous avons aussi intégré des NSs au sein d'un empilement transparent et conducteur de type oxyde/métal/oxyde, dans le but de remplacer l'électrode classique en oxyde d'indium et d'étain d'une CSO. Le rôle de chaque couche de l'empilement sur le comportement optique de l'électrode est discuté. Les épaisseurs des couches d'une électrode de type ZnO/Ag/ZnO ont été optimisées. / Thin-film solar cells are able to produce low-cost energy without greenhouse gas emissions. In order to increase devices performance, we investigate the impact of metallic nanostructures (NSs) integrated in organic solar cells (OSC). These NSs can generate scattering effects and surface plasmon resonances. Using FDTD modeling, we demonstrate that plasmon engineering can be used to increase light absorption in a photoactive material while minimizing the energy lost as heat in the NSs. The influence of opto-geometrical parameters of plasmonic structures in organic material is investigated (diameter, position of particles in the layer and period of spherical particles array). Experimentally, silver NSs are deposited by evaporation and incorporated into an organic layer. We measured an optical absorption enhancement in the spectral range useful for photo-conversion. Three different architectures of plasmonic OSC are fabricated and characterized by SEM, TEM and ToF-SIMS, then modeled, allowing us to identify some technological obstacles and to propose possible improvements. We also integrated NSs inside a transparent and conductive multilayer stack composed of oxide/metal/oxide, in the aim of replacing the traditional indium tin oxide electrode of a OSC. The role of each layer of the stack on the electrode optical behavior is discussed. Layers thicknesses of a ZnO/Ag/ZnO electrode were optimized. Cellule solaire organique Nanoparticule métallique Plasmonique Modélisation FDTD Caractérisation Électrode oxyde/métal/oxyde Organic solar cell Metallic nanoparticle Plasmonics FDTD modelization Characterization Oxide/metal/oxide electrodes
127	Nanostructures plasmoniques de type coeur-coquille métal-diélectrique pour cellules photovoltaïques organiques / Core-shell metal-dielectric plasmonic nanostructures for organic photovoltaic cells N'Konou, Kokou Kekeli David 18 April 2018 (has links) L'une des approches pour améliorer les performances des cellules solaires organiques, sans augmenter l'épaisseur de la couche photoactive, consiste à incorporer des nanoparticules (NPs) métalliques dans cette couche ou à proximité pour bénéficier de la diffusion de la lumière incidente ou de résonances de plasmons de surface localisés. Cependant, ces NPs métalliques peuvent engendrer des recombinaisons des porteurs de charges électriques, créer des court-circuits ou favoriser l'extinction des excitons au contact du métal. Une solution est alors de protéger ces NPs métalliques par un revêtement diélectrique (coquille ou couche fine). L'objectif de cette thèse est d'étudier l'influence de nanostructures de type cœur–coquille (métal-diélectrique) sur les performances optiques et photoélectriques de cellules solaires organiques, à l'aide de modélisations numériques et de réalisations expérimentales. Dans un premier temps, une étude numérique prédictive, basée sur une modélisation par méthode FDTD, nous a permis d'analyser l'influence de paramètres architecturaux et opto-géométriques sur les propriétés optiques de cellules solaires plasmoniques. Par la suite, nous avons synthétisé et caractérisé des nanosphères (NSs) avec un cœur métallique en argent ou en or recouverts d'une fine coquille de silice. L'incorporation de NSs Ag@SiO2 synthétisées (voie humide) ou de NPs Ag/SiO2 déposées par évaporation (voie sèche) dans des cellules solaires à architecture inverse ont permis d'augmenter le photocourant de 12% ou de 18% respectivement par rapport à la cellule de référence (sans NSs). / One of the approaches to improve the organic solar cells performance without increasing the thickness of the photoactive layer is to incorporate metallic nanoparticles (NPs) in this layer or in its proximity to have benefited from light scattering or localized surface plasmon resonance effects. However, these NPs can generate charge carriers recombination, short circuits or exciton quenching due to the contact with the metal. A solution is then to coat these MNPs with a dielectric (thin shell or layer) to protect them. The objective of this thesis is to study the influence of metaldielectric coreshell nanostructures on the optical and photoelectric performances of organic solar cells, by using numerical modeling and experiments. First, a predictive numerical analysis by FDTD modeling allowed us to optimize the influence of architectural and optogeometric parameters on optical properties of plasmonic organic solar cells. Silver or gold core nanospheres (NSs) coated with a thin silica shell were synthesized and characterized. Finally, the integration of chemically synthesized Ag@SiO 2 NSs (wet process) or Ag/SiO 2 NPs deposited by evaporation (dry process) in inverted organic solar cells has increased the photocurrent by 12% or 18%, respectively, compared to the reference cell(without NSs). Cellule solaire organique Plasmonique Modélisation FDTD Absorption Organic solar cell Plasmonics FDTD modeling Absorption
128	Estudos sobre fotogeração, efeitos de interfaces e de transporte de portadores em células solares orgânicas / Studies about photogeneration, interface effects, and charge carrier transport in organic solar cells Coutinho, Douglas José 18 June 2015 (has links) Esta tese teve por objetivo, desde seu início, investigar as propriedades elétricas de um dispositivo ITO/PEDOT:PSS/P3HT:PCBM/Ca/Al, o qual é uma estrutura bem conhecida de célula solar orgânica do tipo de heterojunção de volume (bulk-heterojunction – BHJ), e com isso dar uma contribuição à melhora de seu desempenho. Porém, o primeiro passo foi introduzir no Grupo de Polímeros Bernhard Gross, um método eficaz de produzir células solares do tipo BHJ com boa eficiência e reprodutibilidade. Esse primeiro desafio foi alcançado com sucesso. A eficiência (η) de um dispositivo fotovoltaico de multicamadas depende de muitos fatores. Dentre eles, uma boa superposição entre o espectro solar e a curva de absorção da camada absorvedora, uma excelente conversão da energia luminosa em portadores de carga, um eficiente processo de condução e uma perda mínima por recombinação e armadilhamento de portadores. Além disso, a compatibilidade eletrônica entre as interfaces tem um papel fundamental na definição na tensão de circuito aberto (VOC), no valor da corrente de curto-circuito (JSC), e no fator de preenchimento (FF). Baseado nesses efeitos, realizamos uma série de medidas experimentais, que auxiliado por um modelo teórico proporcionaram um estudo detalhado da evolução em função da temperatura da mobilidade dos portadores (μ) e de seu tempo de vida (τ). Os principais experimentos nessa tese foram realizados em diferentes temperaturas (entre 100 e 340 K). Foram eles: medidas de fotocorrente - Jph(V), a técnica de foto-CELIV, e medidas de transiente de fotovoltagem (TPV). Em paralelo, desenvolvemos o modelo teórico para a descrição analítica de Jph(V) que assumiu contatos não-injetores e que o livre caminho médio (w = μτF) de elétrons e buracos eram iguais (F é o campo elétrico). Nos ajustes teórico/experimental usamos a probabilidade de dissociação dos estados de transferência de carga (P) e o produto μτ como parâmetros de ajuste. A condição na qual o livre caminho médio é maior que a espessura da amostra (w >> L) reproduz a corrente de saturação reversa, Jsat = qGPLG é a taxa de geração dos éxcitons. Para w << L, a fotocorrente varia linearmente com o livre caminho médio, ou seja, J(F) = qGPμτF. A comparação entre os resultados experimentais e os teóricos permitiram, além da obtenção da evolução das grandezas μ e τ com a temperatura, estabelecer uma relação efetiva entre os parâmetros da célula (η, JSC, e FF) e as propriedades elétricas da camada ativa P3HT:PCBM. As medidas termo-mecânicas (DMA) forneceram informações adicionais sobre mudanças estruturais da camada ativa, as quais foram correlacionadas com variações dos parâmetros da célula e com fatores de perda. Finalmente, medidas de tempo-de-voo (TOF) e de CELIV foram realizadas para estudos mais detalhados sobre mecanismos de transporte ao longo da camada ativa, a efeitos de injeção pelos eletrodos, e para o entendimento de efeitos de degradação pela ação do oxigênio. / This thesis aims to investigate electrical characteristics of an ITO/PEDOT:PSS/P3HT:PCBM/Ca/Al device, which is a well-known structure of a bulk-heterojunction (BHJ) organic solar cell, and to contribute to improve its performance. However, the first step was to introduce in the Group of Polymer Bernhard Gross an effective method for producing BHJ solar cells, manufacturing thus devices exhibiting excellent performance and reproducibility. This thesis aims to investigate electrical characteristics of an ITO/PEDOT:PSS/P3HT:PCBM/Ca/Al device, which is a well-known structure of a bulk-heterojunction (BHJ) organic solar cell, and to contribute to improve its performance. However, the first step was to introduce in the Group of Polymer Bernhard Gross an effective method for producing BHJ solar cells, manufacturing thus devices exhibiting excellent performance and reproducibility. This goal was successfully achieved. The good efficiency (η) of a multilayer photovoltaic cell depends on many factors, including good overlap between the solar spectrum and the light absorbing layer, an excellent conversion of the absorbed light energy in pairs of electronic carriers, efficient charge transport and the minimum losses by recombination or by the action of deep traps for the carriers. Furthermore, the compatibility between electronic interfaces plays a crucial role in defining the open-circuit voltage (VOC) and the value of short-circuit current (JSC), and on the fill factor (FF). Anchored on these effects, we carried out a series of experiments, aided by a theoretical modeling, which provided a detailed study of the temperature evolution of fundamental electric quantities such as carrier mobility (μ) and its lifetime (τ). These studies were performed with the help of different experiments: photocurrent in function of the applied voltage  Jph(V), Photo-CELIV technique, and Transient Photovoltage (TPV) measurements, which were carried out at several temperatures in the 100 to 340 K range. In parallel, we developed an analytical model for Jph(V) that assumed non-injecting contacts and equal mean-free-paths for electrons and holes. The theoretical/experimental entities used as fitting parameters were the charge-transfer-state dissociation probability (P) and the μτ product. The condition in which the mean-free-path (w = μτF) is higher the sample thickness (L), the model reproduces the experimental reverse saturation current, Jsat = qGPL, which is coincident with the experimental value. F is the internal electric field and G is the generation rate of excitons by the absorbed light. When w << L, J(F) = qGPμτF, which is also coincident with experimental behavior. The confrontation between the experimental results and the theoretical model provided, in addition to the study of the evolution of μ and τ with temperature, to establish a more effective relationship between the parameters (η, JSC, e FF) of the cell and the electrical properties of the P3HT:PCBM active layer. Thermomechanical analysis (DMA) provided additional information of structural changes of active layer, which can be correlated with change in the loss factor and in the cell parameters. Finally, Time-of-Flight (TOF) and CELIV techniques were used in the more accurate study of charge transport along the active layers, effects of injection by the electrodes, and the degradation effect caused by oxygen. Células solares orgânicas Device modelling Efeitos de interface foto-CELIV Fotocorrente Interface effects Modelagem de dispositivo Organic solar cells photo-CELIV Photocurrent Tempo-de-voo Time-of-flight
129	PREPARAÇÃO DE COMPOSTOS ORGÂNICOS COM POTENCIAL APLICAÇÃO EM DISPOSITIVOS FOTOVOLTAICOS: AVALIAÇÃO DE PROPRIEDADES FOTO-FÍSICAS E ELETROQUÍMICAS Klider, Karine Cristina Carrilho Weber dos Santos 27 July 2016 (has links) Made available in DSpace on 2017-07-20T12:40:19Z (GMT). No. of bitstreams: 1 Karine Klider.pdf: 4696661 bytes, checksum: 1625309038e6d64e39214301b4f96f7b (MD5) Previous issue date: 2016-07-27 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / In this study, we evaluated the optical and electrochemical properties of organic compounds of different types in order to analyze their potential for application active layer in photovoltaic devices. The work was divided into three parts. The first discloses the preparation and characterization of a derivative of 1,8-naphthalimide chromophore prepared from the reaction with a benzonitrile unit (also synthesized and characterized in this work). The BID-NB compound showed optical and electrochemical properties equivalent of the chromophore with optical and electrochemical band gap of 3.41 eV and 2.19 eV. Photovoltaic devices using bilayer architecture, constructed with the compound as the active layer, reached 0.9% of power conversion efficiency (PCE) and a current density at short circuit of 5.68 mA cm-2 by using the C70 fullerene as electron acceptor layer, and 1,8-diiodoocthane as additive in the solution for active layer deposition. The second part the work described the preparation of conjugated molecules (with electron donor acceptor characteristics) from the indigo dye modification by addiction of thiophene units. It was found that increasing number of thiophene units resulted in better opto-electrochemical properties. The molecule that showed the best behavior, DHT-IND, presented optical and electrochemical band gap of 1.64 and 1.45 eV respectively. Despite the low band gap value, the bulk heterojunction (BHJ) solar cell constructed with a 1: 3 mixture of DHT-IND and PC71BM as active layer, showed PCE of 0.7% and current density at short circuit of -4.59 mA cm-2. The fill factor (FF) was 26%. In the third part of this work we evaluated the photocurrent generation by the copolymer PPV/DCN-PPV formed by DCN-PPV chains attached to PPV chain. The evaluation performed as film deposited on a glass substrate containing ITO coated, which has exposed to a LED ilumination. After irradiation the copolymer generated current of A cm-2 (unstable), and -2 A cm-2 (stable). / Neste trabalho foram avaliadas as propriedades ópticas e eletroquímicas de deferentes compostos orgânicos, e analisar suas potencialidades para aplicação como camada ativa em dispositivos fotovoltaicos. Dividiu-se o trabalho em três partes. A primeira revelou a preparação e caracterização de um derivado do cromóforo 1,8-naftalimida, preparado a partir da reação com uma unidade de benzonitrila previamente preparada e caracterizada. O composto 4-(2-(1,3-dioxo-1H-benzo[de]isoquinolin-2(3H)-il)etoxi)-2,5-dimetilbenzonitrila, ou BID-NB, apresentou propriedades ópticas e eletroquímicas equivalentes às do cromóforo, com band gap óptico de 3,41 eV e eletroquímico de 2,19 eV. Dispositivos fotovoltaicos de bicamada foram construídos com o composto BID-NB como camada ativa, sendo que a eficiência máxima de conversão foi de 0,9% com uma densidade de corrente de curto circuito de -5,68 mA cm-2. O dispositivo que auferiu tais resultados foi construído com o fulereno elétron-aceptor C70, e com o auxilio do aditivo 1,8-diiodooctano na deposição da camada ativa. A segunda parte do trabalho consistiu da preparação de moléculas conjugadas do tipo doador/aceptor de elétrons, a partir da modificação do corante índigo com unidades de tiofenos. Constatou-se que o aumento da quantidade de unidades de tiofenos nas moléculas favoreceu suas propriedades opto-eletroquímicas. O composto 7,14-bis(3``,4`-diexil-[2,2`:5`,2``-tertiofen]-5-il)diindolo[3,2,1-de:3`,2`,1`-il][1,5]naftiridina-6,13-diona, ou DHT-IND, foi o que apresentou os menores valores de band gap óptico e eletroquímico, nos valores de 1,64 e 1,45 eV respectivamente. O dispositivo fotovoltaico de heterojunção, construído a partir da mistura 1:3 de DHT-IND e PC71BM como camada ativa, apresentou eficiência de conversão de 0,7% e densidade de corrente de -4,59 mA cm-2. Na terceira parte deste trabalho avaliou-se geração de fotocorrente em um copolímero formado por blocos de PPV ligados a blocos de DCN-PPV (PPV/DCN-PPV). A avaliação foi efetuada na forma de filme sobre um substrato de vidro contendo ITO, o qual foi exposto a iluminação de LED. O copolímero gerou corrente de até -4 A cm-2 (instável), e de -2 A cm-2 (estável) após iluminação. Semicondutores Orgânicos 1,8-Naftalimida Indigo DCN-PPV Célula Solar Orgânica Organic Semiconductors 1,8-naphthalimide Indigo DCN-PPV Organic Solar Cell
130	Amélioration des performances des cellules solaires organique par l'ingénierie de bandes aux interfaces électrodes semi - conducteurs / Improvement of the performance of organic solar cells by band engineering at semiconductor electrode interfaces Obscur, Jean-Charles 21 June 2017 (has links) Le contexte actuel de forte croissance des besoins en énergie dans le monde nécessite une diversification de sa production, notamment vers des sources renouvelables tout en limitant autant qu’il est possible l’émission de gaz à effet de serre. Parmi les énergies renouvelables une des plus prometteuses et abondantes est l’énergie solaire et il apparaît évident que l’énergie solaire, thermique ou photovoltaïque, représente un enjeu crucial pour diminuer la consommation d’énergie fossile. Actuellement 90 % des générateurs solaires sont élaborés en silicium cristallin, ce qui pose un problème d’approvisionnement en matière première, les producteurs de silicium n’ayant pas su anticiper la forte expansion de la filière solaire. Des concepts innovants présentent une forte potentialité en termes de coût de production et d’application, notamment les filières organiques et hybrides (organique/oxyde métallique). En Europe, la France est très active dans ce domaine de recherche, en particulier en ce qui concerne l’utilisation de nouveaux matériaux nanostructurés organiques ou de structures hybrides. C'est pourquoi Disasolar, une start-up française spécialisée dans le photovoltaïque souple, souhaite développer cette activité en élaborant des modules solaires souples par impression jet d'encre. Les objectifs de cette thèse sont d'étudier des nouveaux matériaux d'interface imprimables et d'évaluer l'effet de la dimension des nanoparticules sur la topologie et les performances des dispositifs. Et dans un deuxième temps l'étude portera sur l'impression des matériaux d'interface et la stabilité des cellules solaires organiques. / The current context of strong growth in energy demands in the world requires diversification of its production, in particular towards renewable sources while limiting as far as possible the emission of greenhouse gases. Among the most promising and abundant renewable energies is solar energy and it is evident that solar, thermal or photovoltaic energy represents a crucial issue to reduce the consumption of fossil energy. Currently 90% of the solar generators are made of crystalline silicon, which poses a problem of supply of raw material, as silicon producers did not know how to anticipate the strong expansion of the solar sector. Innovative concepts present a high potential in terms of cost of production and application, in particular organic and hybrid (organic / metal oxide) dies. In Europe, France is very active in this area of research, particularly with regard to the use of new organic nanostructured materials or hybrid structures. This is why Disasolar, a French start-up specializing in flexible photovoltaics, wants to develop this activity by developing flexible solar modules by inkjet printing. The objectives of this thesis are to study new printable interface materials and to evaluate the effect of nanoparticle size on the topology and performance of devices. And secondly, the study will focus on the printing of interface materials and the stability of organic solar cells. Cellule solaire organique (OPV) Couche d’interface Nanoparticules Impression jet d’encre Stabilité Vieillissement Encapsulation Organic solar cell (OPV) Interface layer Nanoparticles Inkjet printing Stability Aging Encapsulation 621.312 44

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